In the figure shown, the acceleration of block of mass `m_(2)` is `2m//s^(2)`. The acceleration of `m_(1)` `:`

Block A is kept on block B as shown in figure. It is known that acceleration of block A is 2 m//s^(2) towards right and acceleration of block B is 3 m//s^(2) towards right under the effect of unknown forces. Direction of friction force acting on A by B (mu_(AB) = 0.3)

If acceleration of block B is 4 m//s^(2) upward & that of C is 6 m//s^(2) downward. Find acceleration of A :-

In the figure shown the man of mass 60kg is lowering a block of mass 10kg with an acceleration of 2m//s^2 . Find the reading of the machine.

In the figure shown the man of mass 60kg is lowering a block of mass 10kg with an acceleration of 2m//s^2 . Find the reading of the machine.

In the figure shown the man of mass 60kg is liftinga block of mass 10kg with an acceleration of 5m//s^(2) . Find reading of the machine.

In the arrangement shown the fixed pulley is massless and frictionless. If the acceleration of block of mass 1kg is (30)/(x)m//s^(2) . Find the value of x .

At a certain moment of time, acceleration of the block A is 2 m//s^(2) . Upward and acceleration of block B is 3 m//s^(2) upward. The acceleration of block C is ( masses of pulleys and string are negligible )

In the figure shown the acceleration of A is, bara_(A)=(15hati+15hatj)m//s^(2). If A is sliding on B then the acceleration of B is.

As shown in the figure, if acceleration of M with respect to ground is 5m//s^(2) , then :

In the pully system shown, if radii of the bigger and smaller pulley are 2m and 1m respectively and the acceleration of block A is 5 m//s^(2) in the downward direction, then the acceleration of block B will be